On the systematics of Phlebotomus betisi and two new related species from Laos with proposal of the new subgenus Lewisius

Phlebotomus betisi was described from Malaysia and classified after its description in the subgenus Larroussius. It was the only species to have a pharyngeal armature composed of dot-like teeth and an annealed spermatheca whose head is carried by a neck in females. Males were characterized by having a style bearing five spines and a simple paramere. The study of sandflies originating from a cave in Laos enabled us to discover and describe two sympatric species close to Ph. betisi Lewis & Wharton, 1963 and new for Science: Ph. breyi Vongphayloth & Depaquit n. sp., and Ph. sinxayarami Vongphayloth & Depaquit n. sp. They were characterized morphologically, morphometrically, geomorphometrically, molecularly, and proteomically (MALDI-TOF). All approaches converged to validate the individualization of these species whose morphological differential characters lay in the two genders by the observation of the interocular suture and by the length of the last two segments of the maxillary palps. In males, the length of the genital filaments discriminates these species. Females are distinguished by the length of the ducts of the spermathecae as well as by the narrow or enlarged shape of the neck bearing their head. Lastly, the particular position of the spines of the gonostyle coupled with molecular phylogeny led us to remove these three species from the subgenus Larroussius Nizulescu, 1931 and to classify them in a new subgenus: Lewisius Depaquit & Vongphayloth n. subg.

The subgenus Larroussius was created by Nitzulescu in 1931 [30] using Ph. major Annandale, 1910 [4] as the type species. Based on morphological characters, the Larroussius subgenus was originally described as follows: (i) cibarium without armature, (ii) spermathecae segmented with a long (variable) terminal process (neck) carrying the terminal knob, and (iii) pharynx similar to that of Ph. major; Theodor, 1948 [46] proposed: (i) short style with five long spines with two terminal spines and three spines near the middle of segment, (ii) simple parameres with a club-shaped apex, (iii) long parameral sheath (aedeagus) of variable shape, (iv) pharynx with armature of numerous small point-like teeth, and (v) spermathecae segmented with a long terminal process.
In Southeast Asia (SE-Asia), the only known species classified in the subgenus Larroussius is Ph. betisi Lewis & Wharton, 1963 [29]. This species was described from eight females caught in a cave in Betis, Gua Musang (Malaysia). These authors noted that Ph. betisi spermathecae look like those of Ph. major (i.e., close to those of Larroussius) but noticed that the bead-like segments and the narrowness of the process (meaning the terminal knob (head) carried by a neck) are unusual and that the systematic position of Ph. betisi could be clarified by the discovery of a male specimen. In 1978, Lewis [28] classified Ph. betisi in the subgenus Larroussius, a position adopted in papers published later by Lewis, 1982 [27]; Artemiev & Neronov, 1984 [9]; and by Seccombe et al., 1993 [43]. In 2008, the male of Ph. betisi was described by Khadri et al. [25] from specimens caught in Kota Gelanggi cave of Pahang, 20 km away from the type-locality. In this description, the authors indicated that Ph. betisi male specimens could be classified in the subgenus Larroussius by the morphology of the genitalia (meaning a gonostyle with 5 spines, a simple paramere without club-shaped apex or without a ventral tubercle, and the lack of basal process on the gonocoxite). The position of spines on the style, however, was different from that of other Larroussius specimens.
In the present paper, we describe two species new to science from Laos, closely related to Ph. betisi, and propose to create a new subgenus to include these three species.

Sandfly collection
Sandflies were collected between May 11 and May 17, 2019 from karstic limestone near the entrance of Pha Nok Kok cave in Feung district, Vientiane province, Laos (locality: Fig. 1). Sandflies were collected overnight (from 5:00 pm to 6:00 am) using standard CDC light traps (John W. Hock Company, Gainesville, FL, USA). Sandfly samples were then sorted and stored in 95% ethanol. An aliquot was stored dry in silica gel at -20°C then transferred to the laboratory for further analysis.

Sample processing and morphological analysis
Specimens stored in 95% ethanol were mounted: in toto for morphological analysis: head, thorax, wings and genitalia were cut-off in a drop of ethanol. Soft tissues were lysed in a bath of 10% KOH then bleached in Marc-André solution, and mounted between microscope slide and cover slide in Euparal â for species identification after dehydration in successive alcoholic baths. -Partially for molecular studies: head, wings and genitalia were cut-off and mounted directly in Euparal â as described above. Thorax and abdomen were transferred to an Eppendorf 1.5 mL tube with the same labelling as the slide and stored at -20°C until analysis. All engorged females were processed according to this protocol.
For MALDI-TOF, dry specimens stored at -20°C were prepared as follows: head, wings and genitalia were cut-off and mounted directly in either Macroinvertebrate Mounting Medium (Polysciences, Inc. Warrington, PA, USA) or in Euparal Ò as described above. Thorax and abdomen were transferred separately to two Eppendorf 1.5 mL tubes with the same labelling as that of the slide and stored at -20°C until MALDI-TOF (using the thorax) and molecular analysis (using the abdomen).
The mounting slides were observed on an Olympus BX50 microscope coupled with a DP 26 Olympus camera. Measurements and counting of several characters were performed by using Stream Essentials software (Olympus, Tokyo, Japan), as previously explained [11]. Drawings were made using the camera lucida installed on the microscope. The abdomen of the specimen stored in a 1.5 mL vial was processed by adding 0.5 mL of 1Â Phosphate Buffered Saline (PBS) and Lysing Matrix E zirconium beads (MP Biomedicals, Santa Ana, CA, USA) and homogenized for 10 min at a vibration frequency of 25/s in a TissueLyser II system (QIAGEN, Hilden, Germany). After grinding, beads and tissues were spun down by centrifugation for 5 min at 3000 rpm. To obtain total nucleic acid, 100 lL of each sample were extracted and purified using a NucleoSpin Ò 8 extraction kit, following the manufacturer's protocol and using an elution volume of 100 lL. All polymerase chain reaction (PCR) amplifications were carried out in a 50 lL volume containing 5 lL of extracted DNA and 45 lL PCR Master Mix (Promega, Madison, WI, USA), containing 50 pmol of each primer targeting cyt b: C3B-PDR (5 0 -CAYATTCAACCWGAATGATA-3 0 ) and N1N-PDR (5 0 -GGTAYWTTGCCTCGAWTTCGWTATGA-3 0 ), according to previously published conditions [17]. Sequencing reactions were performed using a BigDye Terminator v1.1 cycle sequencing kit (Applied Biosystems, Waltham, MA, USA). Sequence chromatograms from both strands were obtained on an automated sequence analyzer ABI3500XL (Applied Biosystems).
Phylogenetic analysis was based on aligned sequences. The maximum likelihood (ML) tree was constructed by MEGA 11 [45] using the substitution models selected by Model test [36] with an Akaike information criterion (AIC) of HKY85 [21]. We have included five specimens of Ph. breyi n. sp. and five specimens of Ph. sinxayarami n. sp. as well as two Malaysian specimens of the closely related Ph. betisi and 53 specimens representing 53 species of the genus Phlebotomus, as indicated in Table 1. Idiophlebotomus longiforceps was selected to serve as an outgroup.

Blood meal analysis
The abdomen of each engorged female was processed individually. Total DNA was extracted with a QIAamp DNA mini kit (QIAGEN GmbH), according to the manufacturer's recommendations. The extracted DNA was eluted in a final volume of 100 lL of AE buffer. For each extraction run, we included a positive control.
To check the bloodmeal origin of engorged females, we amplified the prepronociceptin (PNOC) gene using PNOC-F (forward): 5 0 -GCATCCTTGAGTGTGAAGAGAA-3 0 and PNOC-R (reverse): 5 0 -TGCCTCATAAACTCACTGAACC-3 0 primers, according to the conditions described in the literature [20]. Amplicons were analyzed by electrophoresis in 1.5% agarose gel containing gelgreen. Direct sequencing in both directions was performed with the primers used for DNA amplification.

MALDI-TOF MS Analysis
Matrix Associated Laser Desorption-Ionization -Time Of Flight mass spectrometry (MALDI-TOF) was performed as already described [22]. Briefly, thoraxes, including legs of the specimens, were placed in formic acid (10 lL; Sigma-Aldrich, Lyon, France) and manually ground with a Teflon pestle. Acetonitrile (10 lL Sigma-Aldrich) was then added and after a brief centrifugation step (2 min at 10,000 rpm), 1 lL of supernatant was spotted on a 96-well steel MALDI target plate (Bruker Daltonics, Champs-sur-Marne, France). Specimens were deposited in quadruplets. After complete drying,  The Bruker "MALDI Biotyper Preprocessing Standard Method" was used for the creation of main spectra profiles (MSP). High-quality spectra were selected for incrementing the local Ph. Larroussius database (at least 10 good quality spectra by MSP). Hierarchical cluster analysis (HCA) was performed using both the Euclidean and correlation method and the Ward algorithm for clustering with the MSP dendrogram tool of Compass Explorer.

Geometric morphometric analysis
Geometric morphometric analysis [37] was carried out on 50 female sandfly wings (Ph. sinxayarami n = 39 and Ph. breyi n = 11) and 19 male sandfly wings (Ph. sinxayarami n = 10 and Ph. breyi n = 9). Briefly, fuchsin-stained wings were photographed under Â100 magnification. Work files were then built with TPS Util Ó version 1.76, and 16 landmarks (LM) were digitized with TPSDig Ó version 1.40 [42]. Coordinates of scaled 16 landmarks were imported in R software Version 1.4.1103 [41] and processed with the geomorph package [1,10]. Coordinates were aligned by performing a procrustes superimposition and centroid sizes (CS) were computed. Disparity between CS from the different novel species and between sexes was tested by means of a Wilcoxon test with p-values < 0.05 considered significant. Main shape LM disposition from male (n = 8) and female (n = 3) Ph. betisi was computed to serve as a reference for comparison with Ph. breyi and Ph. sinxayarami. Deformation grids were plotted to identify the main differences between LM positions. Principal Component Analysis (PCA) was performed on Ph. breyi and Ph. sinxayarami to assess whether morphologic differences could be used to separate these species. Plots were generated with R packages geomorph, factominer, factoextra and ggplot2 [26,50].

Cytochrome b gene
The 405 bp database included 223 variable sites and 182 informative sites for parsimony. A maximum likelihood tree based on this database is shown in Figure 2. The estimation of evolutionary divergence over sequence pairs between and within subgenera is provided in Table 2 and between and within the species Ph. betisi, Ph. breyi n. sp. and Ph. sinxayarami n. sp. in Table 3.
The maximum likelihood phylogenetic tree of cyt b showed that Ph. betisi from Malaysia, Ph. breyi and Ph. sinxayarami are grouped together. The subgenus Madaphlebotomus, although appearing as paraphyletic, is a sister-group of these species and is separated from subgenus Larroussius with strong maximum statistical support (bootstrap = 100%) (Fig. 2). This result confirms our observations on morphologic characters of Lewisius n. subg. (as described below). Phylogenetic analysis also supports our morphologic association of male and female. Phlebotomus breyi of both sexes have long palps and incomplete interocular sutures. Females have long spermathecal ducts and males have long aedeagal ducts. Both sexes of Ph. sinxayarami have shorter palps, especially p4, and complete interocular sutures. Females have shorter spermathecal ducts and males have shorter aedeagal ducts than those of Ph. breyi (see details in description below).
The genetic distances between and within subgenera and species are listed in Table 2 and Table 3, respectively and highlight important differences.

Bloodmeal analysis
The blood meal of one engorged Ph. sinxayarami n. sp. female was successfully identified. The sequence homology was >99% with several sequences (including GenBank accession number XM_044939717.2) of water buffalo (Bubalus bubalis) that were observed around the entrance of Pha Nok Kok cave.

Wing morphometrics
Centroid sizes of Ph. breyi and Ph. sinxayarami are represented in Figure S1. The Wilcoxon test performed on CS showed no differences between the size of females from Ph. breyi and Ph. sinxayarami (p-value = 0.1622). In contrast, a significant difference between the two male populations was found (p-value = 2.646 Â 10 À5 ). Procrustes analysis on mean shapes showed that the differences between Ph. breyi and Ph. sinxayarami rely mostly on deviations of LM Nos. 1 and 12 (Fig. S2). Plots of PCA individuals were able to discriminate between the two species, although both plots represented a small proportion of the total variance (56.7% and 47.3% for males and females, respectively) ( Fig. 3).

MALDI-TOF
High-quality spectra were obtained from all 12 specimens of Lewisius n. subg. All spectra returned lower log-score values than threshold (1.7) when matched against our existing Ph. Larroussius group MSP database (data not shown). Hierarchical clustering (Fig. 4) allows one to (i) group all spectra ( Fig. S3) from Ph. breyi n. sp. and Ph. sinxayarami n. sp. into a cluster distinct from spectra of specimens of the Larroussius group, and (ii) reliably discriminate between spectra from the two new species. The PCA analysis also enabled us to separate

Description of new taxa
Consensual terminology has been used in this description [18].
In our opinion, the species described below cannot be included in the subgenus Larroussius (see Discussion). 3 Lewisius n. subg. is defined by (i) pharynx with armature of numerous small point-like teeth similar to those of Larroussius, (ii) gonostyle exhibiting five long spines out of which two are terminal, the upper external implanted subapically, the lower external implanted in the apical third and the inner one in its middle, (iii) simple parameres, (iv) conical parameral sheath, regularly tapering, and (v) segmented spermathecae, bead-like rings with a long terminal process.
Etymology: Lewisius refers to David J Lewis, Medical Entomologist at the Natural History Museum of London, who was a pioneer in the study of Phlebotomine sandflies of South-Eastern Asia and also described Phlebotomus betisi, the type-species of this new subgenus. One male and one female paratype deposited at the Natural History Museum, London, UK (identification numbers NHMUK014908972 and NHMUK014908973).
One female and one male paratype deposited at the Laboratory of Medical Entomology, IPL.
Etymology: Epithet breyi refers to our Entomologist colleague Paul Brey, who created the Institut Pasteur du Laos (IPL) and the laboratory of Medical Entomology/Vector-borne diseases within the IPL.
Note: The authors of the new taxa are different from the authors of this paper: Article 50.1 and Recommendation 50A of the International Code of Zoological Nomenclature [24]. Table 2. Number of base differences per site from averaging over all sequence pairs between subgenera and genera (thin style) and within subgenera (bold style) calculated using a p-distance model on the cyt b dataset. Flagellomere 1 longer than f2 + f3. Presence of two short ascoids never reaching the next articulation from f1 to f8, 1 from f9 and 1 atrophied, 1 from F10 and f11, and no ascoid on f12-f14.
Presence of one simple seta on distal p3; six on p4; more than 25 on p5. No simple seta on p1 and p2.  Labrum 244 lm long. Limit between the labrum and the clypeus difficult to observe.
Little pharyngeal teeth, commonly dot-like, sometimes pointed, and oriented backwards. All teeth are arranged along parallel curved lines.
Absence of sclerotized area.

Abdomen
Tergites ii-v: presence of randomly distributed setae. Tergites ii-vii: absence of tergal papillae. (Fig. 6H) Absence of abdominal rods. Gonocoxite: 223 lm long, 68 lm width, with randomly distributed internal setae, without any tuft. Absence of basal gonocoxal lobe. subg. and reference spectra of our in-house database [22] of the Larroussius subgenus.   Gonostyle: 117 lm long with 5 thick spines (two terminal ones, the superior external implanted subapically, the inferior external situated in the apical third and the internal in its middle). Presence on the holotype, as well as on another specimen, of a gonostyle exhibiting an additional thin basal sixth spine (Fig. 6J).

Genitalia
Absence of accessory setae. Simple paramere 189 lm long with a slight tubercle carrying about 6 setae on its lower side.
Absence of accessory spine between the paramere and the parameral sheath.
Epandrial lobes: 225 lm long, about as long as the gonocoxites, without permanent setae. Flagellomere 1 longer than f2 + f3. Presence of 2 short ascoids never reaching the next articulation from f1 to f13.
Presence of one simple seta on distal p3; seven on p4; about 40 on p5. No simple seta on p1 and p2.
Labrum 309 lm long. Limit between the labrum and the clypeus difficult to observe.
Labial furca closed (Fig. 7B). Cibarium armed with many tiny teeth pointed backwards. Little pharyngeal teeth, commonly dot-like, sometimes pointed and oriented backwards. All teeth are arranged along parallel curved lines.
Absence of sclerotized area.

Abdomen
Tergites ii-v: presence of randomly distributed setae. Tergite VIII and IX not observed. Cerci 133 lm long. Setae were not observed on the X sternite.

Genitalia (Figs. 7G and 7H)
Spermathecae were measured and drawn in Marc-André solution on specimen 356-1 before its remounting in CMCP9 medium. Smooth and thin wall individual ducts 450 lm long (Fig. 7H). Ducts are isodiametric except for a basal slight enlargement (Fig. 7G). Annealed spermathecae with 12 or 13 bead-like rings. Terminal knob (head) carried by a long and narrow neck.
Genital fork without lateral apodemes. One male and one female paratype deposited at the Natural History Museum of London, UK (identification numbers NHMUK014908974 and NHMUK014908975). One female and one male paratype deposited at the Laboratory of Entomology of Institut Pasteur du Laos.
Etymology: Epithet sinxayarami refers to the Sinxayaram temple located close to the cave where the type specimens have been caught.   Occiput with several lines forming a thick stripe in the posterior occiput and a narrow line along the superior part of the eyes.
Flagellomere 1 longer than f2 + f3. Presence of two very short ascoids never reaching the next articulation from f1 to f9, 1 from f10 to f11, and no ascoid on f12 to f14.
Presence of one simple seta on distal p3; four simple setae on p4; about 15 on p5. No simple seta on p1 and p2.
Labrum 191 lm long. Limit between the labrum and the clypeus difficult to observe.
Little pharyngeal teeth, commonly dot-like, sometimes pointed, and oriented backwards. All teeth are arranged along parallel curved lines.
Absence of sclerotized area.
Gonostyle: 105 lm long with 5 thick spines (two terminal ones, two median ones and an intermediate one).
Absence of accessory setae. Simple paramere: 140 lm long with a slight tubercle carrying about 5 setae on its lower side.
Absence of accessory spine between the paramere and the parameral sheath.
Epandrial lobes: 196 lm long, about as long as the gonocoxites, without permanent setae. Flagellomere 1 longer than f2 + f3. Presence of 2 short ascoids never reaching the next articulation from f1 to f11, probably two but the second one is not visible from f12 and no ascoid on f13-f14.
Presence of one simple seta on distal p3; seven simple setae on p4; about 40 on p5. No simple seta on p1 and p2.
Labrum 214 lm long. Limit between the labrum and the clypeus difficult to observe.
Little pharyngeal teeth, commonly dot-like, sometimes pointed and oriented backwards. All teeth are arranged along parallel curved lines.
Absence of sclerotized area.

Abdomen
Tergites ii-v: presence of randomly distributed setae. About 20 setae on tergite VIII. Absence of protuberance on tergite IX. Cerci 118 lm long. Setae not observed on the X sternite.
Genital fork with short lateral apodemes. Tables 4 and 5 summarize the measurements carried out on several male and female specimens of Ph. breyi n. sp., Ph. sinxayarami n. sp., and Ph. betisi.

Discussion
The new species status given to Ph. breyi n. sp. and Ph. sinxayarami n. sp. is very strong. It is based on morphologic, morphometric, geomorphometric, molecular and proteomic arguments even though this last approach was not possible on the specimens of Ph. betisi in our possession that were all preserved in alcohol before being mounted. The association of males and females, in addition to the fact that each of the specimens are sympatric, having all been captured in the same cave, is based on the same evidence, regardless of the approach considered.
From a morphological point of view, the three species are easily individualized.
In both sexes, Ph. betisi and Ph. breyi do not have a complete interocular suture while Ph. sinxayarami owns one. This character is very unusual in the genus Phlebotomus [38] and is rather observed in the American genera Warileya [18]. In the Old World, the genus Chinius also shares a complete interocular suture [15].
For males, the main discriminating character (Tables 4, 5 and 6) between these three species is the f1/f2 + 3 ratio. This ratio is low in Ph. breyi n. sp., intermediate in Ph. sinxayarami and high for Ph. betisi. There is no overlap between the three species for this trait. Moreover, the length of the aedeagal ducts is discriminating: they are very long in Ph. breyi (>478 lm), long in Ph. sinxayarami (331-470 lm) and short in Ph. betisi (311-387 lm). Similarly, the palps (particularly p4 and p5) are short in Ph. sinxayarami while they are long in Ph. breyi and Ph. betisi.
For females, the length of the palps, particularly p4 and p5 are short in Ph. Sinxayarami, while they are long in Ph. breyi and Ph. betisi. The spermathecal ducts of Ph. sinxayarami are longer than those of Ph. breyi. The distal part of the spermatheca bearing the head is similar to a neck and thin in Ph. breyi and in Ph. betisi, while it is enlarged in Ph. sinxayarami.
Until now, Ph. betisi was the only Phlebotomus from Southeast Asia to exhibit in the male a gonostyle bearing five spines associated with a simple paramere, differing from the Phlebotomus of the subgenus Euphlebotomus having a fivespine gonostyle associated with a complex paramere. Females were the only ones of the genus Phlebotomus in this same region to have a pharyngeal framework consisting of small punctiform teeth and annealed spermathecae whose head is carried by a neck like that observed in females of the subgenus Larroussius. This exclusivity in the species described so far prompted the authors to quickly identify the specimens possessing these characters as being Ph. betisi. Paradoxically, this great originality of the characters may have hidden specific diversity which would henceforth prompt us to review all the mentions of Ph. betisi in the literature, starting with those having been used to describe the males, although separated only by about 20 kilometres from the type-locality in Malaysia. A checking of the specimens recorded in Thailand [44] or Vietnam [48,49] is now necessary. Additionally, several records of Ph. major in Southeast Asia [5-7, 23, 32-35, 44] are probably irrelevant and certainly refer to Ph. betisi. We recommend their re-examination.
Interestingly, both males and females did not exhibit any papilla on the 3rd flagellomere. This is completely unusual regarding the genus Phlebotomus. If old descriptions did not mention the record/absence of such papilla on the 3rd flagellomere, recent observations carried out on the genera Phlebotomus and Sergentomyia highlighted every time the presence of such papilla on the 3rd flagellomere for members of the genus Phlebotomus, whereas the species belonging to the genus Sergentomyia never exhibits such papilla [11,13,16,39,40]. This unusual observation means that all species belonging to the subgenus Lewisius n. subg. share a character previously observed in the genus Sergentomyia.
The position of Ph. betisi, Ph. breyi, and Ph. sinxayarami in the subgenus Larroussius does not seem relevant to us. When describing the first species, Lewis & Wharton [29] did not   Theodor, 1948Theodor, , 1958, but the bead-like segments and narrowness of the process are unusual. The discovery of the male would probably clarify the position of Ph. betisi". In 1978, Lewis [28] initially classified Ph. betisi in the subgenus Larroussius then followed by several authors reviewing the classification of sandflies [8,9,27,43]. When they described the male, Khadri et al. [25] indicated that within the Larroussius subgenus, two distal and three median spines on the style were usually present. Phlebotomus betisi differed from other Larroussius males by the position of these spines: two distal, one between these and the two intermediate ones.
This character is sometimes shared by Phlebotomus belonging to the subgenus Euphlebotomus. These morphological characters could thus be sufficient to support the validity of the subgenus Lewisius n. subg. Moreover, the molecular approach (Fig. 2) very clearly individualizes the three species of Lewisius revealing the monophyly of this new subgenus. Molecular phylogeny based on ML analysis of mtDNA cyt b sequences also separates Larroussius from Lewisius very clearly. One can of course doubt the relevance of the cyt b marker in obtaining a robust molecular phylogeny including such varied species. Since position of the subgenera Phlebotomus, Paraphlebotomus, Artemievus and Synphlebotomus are doubtful, and the apparent paraphyly of Paraphlebotomus in the present study contrasts with the robust monophyly obtained on genome-wide data, it was possible to individualize the subgenus Artemievus by excluding Ph. alexandri of Paraphlebotomus [12]. Our goal was not to reconstruct a phylogeny of the genus Phlebotomus but to test the monophyly of Lewisius as well as its relationships with the Larroussius. Moreover, the Lewisius has the subgenus Madaphlebotomus as sister group. This relationship between Phlebotomine sandflies from Madagascar and from Southeast Asia deserves to be explored in the light of more conserved molecular markers.
Proteomic data, based on MALDI-TOF mass spectrometry, are consistent with the molecular analysis. With this technique, a high distance separates spectra from specimens of Larroussius subgenus and those of the subgenus Lewisius. Use of MALDI-TOF is also very promising for identification of the two newly described species Ph. breyi and Ph. sinxayarami. No fresh specimens of Ph. betisi were, however, available for MALDI-TOF analysis, and thus did not allow us to fully test the discrimination capabilities of this technique. The constitution of a MALDI-TOF spectral database for Asian sandflies would be particularly interesting for rapid and inexpensive screening.
Morphometric data are coherent with molecular and proteomic approaches. Differences in sizes of wings between male populations are significant. Nonetheless, the morphometric evidence of this current work does not provide an unequivocal result. Principal Component Analysis of the females showed low segregation, whereas males of the two species were more easily separated.
As a side note concerning the biology of this species, it is worth mentioning that our specimen was captured at the entrance of the cave and that we detected a blood meal from a water buffalo in its abdomen. These buffalo were present in a rice field located below the cave at a distance of about 100 to 200 meters from the entrance. They could not access the cave. This trophic preference thus indicates that Ph. sinxayarami females have to leave the cave in order to take their blood meals outside, and therefore do not remain permanently inside the cave. Presence on f1-f2, f9-f14, and absence on f3-f8 < 500 < 4 2/f1-f9, 1/f10-f11, 0/f12-f14 Presence on f1-f2, f10-f14, and absence on f3-f9 < 500 lm < 4 2/f1-f9, 1/f10-f11, 0/f12-f14 Presence on f1-f2, f12-f14, and absence on f3-f11 > 500 lm> 4 Our study was supported by the National Geographic Society, Grant Number: NGS-KOR-50729R-18 and Institut Pasteur du Laos.